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Transcript
.A Figure 36.1 Plants or pebbles?
KEY
CONCEPTS
36.1
land plants acquire resources both above and
below ground
36.2 Transport occurs by short-distance diffusion or
active transport and by long-distance bulk flow
36.3 Water and minerals are transported from roots
to shoots
36.4 Stomata help regulate the rate of transpiration
36.5 Sugars are transported from leaves and other
sources to sites of use or storage
36.6 The symplast is highly dynamic
r:·~:;;:;und Plants
is good for the net acquisition of water but not for photosynthesis. As a result, stone plants grow very slowly.
This chapter begins by examining structural features of shoot
and root systems that increase their efficiency in acquiring resources. Resource acquisition, however, is not the end of the
story but only the beginning. Once acquired, resources must be
transported to those parts of the plant where they are needed.
The transport of materials, therefore, is critical for the integrated
functioning of the whole plant. A central theme of this chapter is
how three basic transport mechanisms-diffusion, active transport, and bulk flow-work together in vascular plants to transfer water, minerals, and the products of photosynthesis (sugars).
C 0 N C E P T
he Kalahari Desert of southern Africa receives only
about 20 em of precipitation a year, almost exclusively during the summer months, when daytime
temperatures reach a scorching 35-45oC (95-113oF). Many
animals escape the desert heat by seeking shelter underground. A peculiar genus of perennial plants called stone
plants (Lithops) has a similar, mostly subterranean lifestyle
(Figure 36.1). Except for the tips of two succulent leaves that
are exposed to the surface, a stone plant lives entirely below
ground. Each leaf tip has a region of clear, lens-like cells that
allow light to penetrate to the photosynthetic tissues underground. These adaptations enable stone plants to conserve
moisture and avoid the potentially harmful temperatures
and high light intensities of the desert.
The remarkable growth habit of Lithops reminds us that the
success of plants depends largely on their ability to gather and
conserve resources from their environment. Through natural
selection, many plant species have become highly proficient in
acquiring resources that are especially limited in their environment, but there are often trade-offs in such specializations.
For example, the mostly subterranean lifestyle of stone plants
T
764
36.1
nts acquire resources
both above and below ground
Land plants typically inhabit two worlds-above ground, where
their shoot systems acquire sunlight and C02, and below
ground, where their root systems acquire water and minerals.
Without adaptations that allow acquisition and transport of
these resources from these dual sites, plants could not have colonized land.
The algal ancestors of land plants absorbed water, minerals,
and C0 2 directly from the water in which they lived. Transport in these algae was relatively simple because each cell was
close to the source of these substances. The earliest land plants
were nonvascular plants that grew photosynthetic shoots
above the shallow fresh water in which they lived. These leafless shoots had waxy cuticles and few stomata, which allowed
them to avoid excessive water loss while still permitting gas exchange for photosynthesis. The anchoring and absorbing
functions of early land plants were assumed by the base of the
stem or by threadlike rhizoids (see Figure 29.8).
l
I
As land plants evolved and increased in number, competition for light, water, and nutrients intensified. Taller plants with
broad, flat appendages had an advantage in absorbing light.
This increase in surface area, however, resulted in more evaporation and therefore a greater need for water. Larger shoots also
required more anchorage. These needs favored the production
of multicellular, branching roots. Meanwhile, as greater shoot
heights further separated the top of the photosynthetic shoot
from the nonphotosynthetic parts below ground, natural selection favored plants capable of efficient long-distance transport of water, minerals, and products of photosynthesis.
The evolution of vascular tissue consisting of xylem and
phloem made possible the development of extensive root
and shoot systems that carry out long-distance transport (see
Figure 35.10). The xylem transports water and minerals from
roots to shoots. The phloem transports products of photosynthesis from where they are made or stored to where they are
needed. Figure 36.2 provides an overview of resource acquisition and transport in a vascular plant.
Because plant success depends on photosynthesis, evolution has resulted in many mechanisms for acquiring light from
the sun, C0 2 from the air, and water from the ground. Perhaps
just as important, land plants must minimize evaporative loss
of water, particularly in environments where water is scarce.
The adaptations of each species represent compromises between enhancing photosynthesis and minimizing water loss in
the species' particular habitat. Later in the chapter, we'll discuss how plants minimize water loss. Here, we'll examine how
the basic architecture of shoots and roots helps plants acquire
resources.
Shoot Architecture and Light Capture
In shoot systems, stems serve as supporting structures for
leaves and as conduits for the transport of water and nutrients. Variations in shoot systems arise largely from the
form and arrangement of leaves, the outgrowth of axillary
buds, and the relative growth in stem length and thickness.
Leaf size and structure account for much of the outward
diversity we see in plant form. Leaves range in length from
the minuscule 1.3-mm leaves of the pygmy weed (Crassula
erecta), a native weed of dry, sandy regions in the western
United States, to the 20-m leaves of the palm Raphia regalis,
a native of African rain forests. These species represent extreme examples of a general correlation observed between
water availability and leaf size. The largest leaves are generally found in tropical rain forests, and the smallest are usually found in dry or very cold environments, where liquid
water is scarce and evaporative loss from leaves is potentially
more problematic.
The arrangement ofleaves on a stem, known as phyllotaxy, is
an architectural feature of immense importance in light capture.
Through stomata, leaves take in C0 2 and release 0 2 .
Sugars are produced by photosynthesis in the leaves.
Transpiration, the loss of water
from leaves (mostly through
stomata), creates a force within H-- - - - - - - - ,,..1--..
leaves that pulls xylem sap upward .
Water and minerals are
transported upward from
roots to shoots as xylem sap.
Phloem sap can flow both ways
between shoots and roots. It
moves from sites of sugar
production (usually leaves) or
storage (usually roots) to sites of
sugar use or storage.
f-+------------141
Water and minerals
in the soil are 1 1
absorbed by roots.
,. ,.
•
Roots exchange gases with the
spaces of soil, taking in 0 2 and
discharging C0 2 .
1 1air
£ Figure 36.2 An overview of resource acquisition and transport in a vascular plant.
CHAPTER THIRTY-SIX
Resource Acquisition and Transport in Vascular Plants
765
Ground area
covered by plant
' , , ___ ~
'
......
- _,- - ......
Plant A
Leaf area = 40%
of ground area
(leaf area index= 0.4)
.&. Figure 36.3 Emerging phyllotaxy of Norway spruce. This
SEM, taken from above a shoot tip, shows the pattern of emergence
of leaves. The leaves are numbered, with 1 being the youngest. (Some
numbered leaves are not visible in the close-up .)
With your finger, trace the progression of leaf emergence, starting
with leaf number 29. What is the pattern?
IJ
Phyllotaxy is determined by the shoot apical meristem and is specific to each species (Figure 36.3). A species may have one leaf
per node (alternate, or spiral, phyllotaxy), two leaves per node
(opposite phyllotaxy), or more (whorled phyllotaxy). Most angiosperms have alternate phyllotaxy, with leaves arranged in an
ascending spiral around the stem, each successive leaf emerging
about 137.5° from the site of the previous one. Why 137.5°? Mathematical analyses suggest that this angle allows each leaf to get the
maximum exposure to light and reduces shading of the lower
leaves by those above. In environments where intense sunlight
can harm leaves, the greater shading provided by oppositely
arranged leaves may be advantageous.
Plant features that reduce self-shading increase light capture. A useful measurement in this regard is the leaf area index, the ratio of the total upper leaf surface of a single plant or
an entire crop divided by the surface area of the land on which
the plant or crop grows (Figure 36.4) . Leaf area index values
of up to 7 are common for many mature crops, and there is little agricultural benefit to leaf area indexes higher than this
value. Adding more leaves increases shading oflower leaves to
the point that they respire more than photosynthesize. When
this happens, the nonproductive leaves or branches undergo
programmed cell death and are eventually shed, a process
called self-pruning.
Another factor affecting light capture is leaf orientation.
Some plants have horizontally oriented leaves; others, such as
grasses, have leaves that are vertically oriented. In low-light conditions, horizontal leaves capture sunlight much more effectively than vertical leaves. In grasslands or other sunny regions,
however, horizontal orientation may expose upper leaves to intense light, injuring leaves and reducing photosynthesis. But if a
plant's leaves are nearly vertical, light rays are essentially paral766
UNIT SIX
Plant Form and Function
,
Plant B
Leaf area = 80%
of ground area
(leaf area index= 0.8)
.&. Figure 36.4 Leaf area index. The leaf area index of a single
plant is the ratio of the total area of the top surfaces of the leaves to
the area of ground covered by the plant, as shown in this illustration of
two plants viewed from the top.
Would a higher leaf area index always increase the amount of
photosynthesis? Explain.
IJ
lel to the leaf surfaces, so no leaf receives too much light, and
light penetrates more deeply to the lower leaves.
Some other factors that contribute greatly to the outward
appearance and ecological success of plants are bud outgrowth and stem elongation. Carbon dioxide and sunlight are
resources that are more effectively exploited by branching.
However, some plants, such as palms, generally do not branch,
whereas others, such as grasses, have short stems with many
branches. Why is there so much variation in shoot architecture? The reason is that plants have a finite amount of energy
to devote to shoot growth. If they put most of that energy into
branching, they have less to devote toward growing tall, and
they are at increased risk of being shaded by taller plants. If
they put all of their energy into being tall, they are not optimally exploiting the resources above ground. Natural selection has produced shoot architectures that optimize light
absorption in the ecological niche plants naturally occupy.
Plant species also vary in stem thickness. Most tall plants
require thick stems, which enable greater vascular flow to the
leaves and mechanical support for them. Vines are an exception, relying on other structures (usually other plants) to raise
their leaves higher. In woody plants, stems become thicker
through secondary growth (see Figure 35.11).
Root Architecture and Acquisition of
Water and Minerals
Just as carbon dioxide and sunlight are resources exploited by
the shoot system, soil contains resources mined by the root system. The evolution of root branching enabled land plants to
more effectively acquire water and nutrients from the soil, while
also providing strong anchorage. The tallest plant species, including gymnosperms and eudicots, are typically anchored by
I
1
1
1'
~
t
~
strong taproot systems with numerous branches (see Figure 35.2).
Although there are exceptions, such as palms, most monocots
do not reach treelike heights because their fibrous root systems
do not anchor a tall plant as strongly as a taproot system (see
Figure 30.13).
Recent evidence suggests that physiological mechanisms reduce competition within the root system of a plant. Cuttings
from the stolons ofbuffalo grass (Buchloe dactyloides) developed
fewer and shorter roots in the presence of cuttings from the same
plant than they did in the presence of cuttings from another buffalo grass plant. Moreover, when cuttings from the same node
were separated, their root systems eventually began competing
with each other. Although the mechanism underlying this ability to distinguish self from nonself is unknown, avoiding competition between roots of the same plant for the same limited pool
of resources certainly seems beneficial.
Evolution of mutualistic associations between roots and
fungi was a critical step in the successful colonization of land
by plants, especially given the poorly developed soils available
at that time. The very specialized mutualistic associations between roots and fungi are called mycorrhizae (Figure 36.5) .
About 80% of extant land plant species form mycorrhizal associations (discussed in Chapter 31). Mycorrhizal hyphae endow the fungus and plant roots with an enormous surface area
for absorbing water and minerals, particularly phosphate. As
much as 3m of hyphae can extend from each centimeter along
a root's length, facilitating access to a far greater volume of soil
than the root alone could penetrate.
Once acquired, resources must be transported to other
parts of the plant that need them. In the next section, we'll examine the processes that enable resources such as water, minerals, and sugars to be transported throughout the plant.
I25
mm
CONCEPT
CHECK
36.1
1. Why is long-distance transport important for vascular
plants?
2. What architectural features influence self-shading?
3. Why might a crop develop a mineral deficiency after
being treated with a fungicide?
4. Some plants can detect increased levels of light reflected from leaves of encroaching neighbors. This
detection elicits stem elongation, production of erect
leaves, and reduced lateral branching. How do these
responses help the plant compete?
5. Mltfhf.SIIM If you prune a plant's shoot tips, what
will be the short-term effect on the plant's branching
and leaf area index?
For suggested answers, see Appendix A.
C 0 N C E P T
36.2
t occurs by short-distance
diffusion or active transport and
by long-distance bulk flow
Like animals, plants need to transport water and nutrients from
one part of their body to another. How do they do this without
a pumping mechanism like a heart? To answer this question, we
must first look at the basic transport processes of plants.
Transport begins with the absorption of resources by plant
cells. As in any organism, the selective permeability of the
plasma membrane controls the movement of substances into
and out of the celL We examined the transport of solutes and
water across plasma membranes in detail in Chapter 7. Here
we'll review diffusion and active transport in the context of
short-distance transport in plant cells, and then we'll look at
long-distance transport through bulk flow.
Diffusion and Active Transport of Solutes
A Figure 36.5 A mycorrhiza, a symbiotic association of
fungi and roots. The white mycelium of the fungus ensheathes
these roots of a pine tree . The branched, club-shaped roots are often
characteristic of this association . The fungal hyphae provide an
extensive surface area for the absorption of water and minerals.
Recall from Chapter 7 that a solute tends to diffuse down its
electrochemical gradient, the combined effect of the solute's
concentration gradient and the voltage (charge difference)
across the membrane. Diffusion across a membrane is called
passive transport because it happens without the cell directly
using metabolic energy. Active transport is the pumping of a
solute across a membrane against its electrochemical gradient. It is called ~~active" because the cell must expend energy,
usually in the form of ATP, to transport a solute counter to the
net direction in which the solute diffuses.
Most solutes cannot diffuse across the phospholipid bilayer
of the membrane directly. Instead, they must pass through
transport proteins embedded in the membrane. Transport
proteins involved in active transport require energy to function,
CHAPTER THIRTY-SIX
Resource Acquisition and Transport in Vascular Plants
767
II
•
CYTOPLASM -
CYTOPLASM
Proton pump
generates membrane potential
and~ gradient.
@@
@
@@
EIB+
.A Figure 36.6 Proton pumps provide energy for solute
EXTRACELLULAR FLUID
@
.
@
(@,
Cations
for
example) are
driven into the cell
by the membrane
potential.
Transport protein
(a) Membrane potential and cation uptake
transport. By pumping H+ out of the cell, proton pumps produce an
H+ gradient and a charge separation called a membrane potential.
These two forms of potential energy can drive the transport of solutes.
whereas those engaged in passive transport do not. In some cases,
transport proteins bind selectively to a solute on one side of the
membrane and then change shape, releasing the solute on the opposite side. Other transport proteins provide selective channels
across the membrane. For example, membranes of most plant
cells have potassium channels that allow potassium ions (K+) to
pass but not other cations, such as sodium (Na +). Some channels are gated, opening or closing in response to stimuli such as
chemicals, pressure, or voltage. Later in this chapter, we'll discuss
how K+ channels in guard cells function in opening and closing
stomata.
In active transport in plant cells, the most important transport proteins are proton pumps, which use energy from ATP
to pump protons (H+) out of the cell. This movement results in
an H + gradient (proton gradient), with a higher H + concentration outside the cell than inside (Figure 36.6). The H + gradient across the membrane is a form of potential (stored) energy,
and the flow of H + back into the cell can be harnessed to do
work. The movement of H + out of the cell also mal<es the inside of the cell negative in charge relative to the outside. This
charge separation across the membrane contributes to a voltage called a membrane potential, another form of potential
energy that can be harnessed to perform cellular work.
Plant cells use the energy in the H + gradient and membrane potential to drive the active transport of many different
solutes. For example, the membrane potential generated by
proton pumps contributes to the absorption of K+ by root
cells (Figure 36.7a). In the mechanism called cotransport, a
transport protein couples the diffusion of one solute (H+)
with active transport of another (N0 3 - in Figure 36.7b).
The "coattail" effect of cotransport is also responsible for
absorption of neutral solutes, such as the sugar sucrose, by
plant cells (Figure 36.7c). A sucrose-H + cotransporter couples movement of sucrose against its concentration gradient
with movement of H + down its electrochemical gradient.
Diffusion of Water (Osmosis)
To survive, plants must balance water absorption and loss. The
net absorption or loss of water by a cell occurs by osmosis, the
768
UNIT SIX
Plant Form and Function
Cell accumulates
anions (lfiii), for
example) by
coupling their
transport to the
inward diffusion
of
through a
cotransporter.
(8}
(b) Cotransport of an anion with H+
Lt
~
Plant cells can
also accumulate a
neutral solute,
such as sucrose
(&_),by
cotransporting
down the
steep proton
gradient.
(ij}
I
(c) Cotransport of a neutral solute with H+
.A Figure 36.7 Solute transport in plant cells.
diffusion of water across a membrane (see Figure 7.12). What determines the direction of water movement? In an animal cell, if
the plasma membrane is impermeable to the solutes, water will
move from the solution with the lower solute concentration to
the solution with the higher solute concentration. But a plant cell
has an almost rigid cell wall, which adds another factor that affects osmosis: the physical pressure of the cell wall pushing back
against the expanding protoplast (the living part of the cell, consisting of the nucleus, cytoplasm, and plasma membrane). The
combined effects of solute concentration and physical pressure
are incorporated into a quantity called the water potential.
Water potential determines the direction of water movement. The primary idea to keep in mind is that free waterwater that is not bound to solutes or surfaces-moves from
regions of higher water potential to regions of lower water potential if there is no barrier to its flow. For example, if a plant
cell is immersed in a solution that has a higher water potential
than the cell, water will move into the cell. As it moves, water
can perform work, such as cell expansion. The word potential
~
•
in the term water potential refers to water's potential energywater's capacity to perform work when it moves from a region
of higher water potential to a region of lower water potential.
Water potential is al?breviated by the Greek letter \jf (psi,
pronounced "sigh"). Plant biologists measure \jf in units of pressure called megapascals (abbreviated MPa). Physicists have
assigned the value of zero ('I' = 0 MPa) to the water potential
of pure water in a container open to the atmosphere under
standard conditions (at sea level and at room temperature).
One MPa is equal to about 10 atmospheres of pressure. (An atmosphere is the pressure exerted at sea level by the volume of
air extending through the entire height of the atmosphereabout 1 kg of pressure per square centimeter.) The internal
pressure of a plant cell is approximately 0.5 MPa, about twice
the air pressure inside an inflated car tire .
How Solutes and Pressure Affect Water Potential
Both pressure and solute concentration can affect water potential, as expressed in the water potential equation:
t
'I' = 'l's
+ \jfp
where \jf is the water potential, 'l's is the solute potential (osmotic potential), and \jfp is the pressure potential. The solute
potential ('l's) of a solution is proportional to the number
of dissolved solutes. Solute potential is also called osmotic
potential because solutes affect the direction of osmosis.
Solutes are dissolved chemicals, which in plants are typically
mineral ions and sugars. By definition, the 'l's of pure water is 0.
But what happens when solutes are added? The solutes bind water molecules, reducing the number of free water molecules and
lowering the capacity of the water to move and do work. Thus,
{a)
{b)
1 Positive
adding solutes always lowers water potential, and the 'l's of a
solution is always negative. A 0.1 M solution of a sugar, for example, has a 'l's of -0.23 MPa.
Pressure potential (\jfp) is the physical pressure on a solution. Unlike \jfs, \jfp can be positive or negative relative to atmospheric pressure. For example, the water in the nonliving
xylem cells (tracheids and vessel elements) of a plant is often under a negative pressure potential (tension) of less than -2 MPa.
Conversely, much like the air in a balloon, the water in living
cells is usually under positive pressure. Specifically, the cell
contents press the plasma membrane against the cell wall, and
the cell wall, in turn, presses against the protoplast, producing
what is called turgor pressure.
Measuring Water Potential
Now let's put the water potential equation to use. We'll apply
it to an artificial model and then to a living plant cell.
AU-shaped tube can be used to demonstrate water movement across a selectively permeable membrane (Figure 36.8) .
As you consider this model, keep in mind the key point: Water
moves from regions ofhigherwater potential to regions oflower
water potential. The two arms of the U-tube are separated by
a membrane (shown as a vertical dashed line) that is permeable to water but not to solutes. If the right arm of the tube
contains a 0.1 M solution ('l's = -0.23 MPa) and the left arm
contains pure water ('l's = 0), and there is no physical pressure
(that is, \jfp = 0), the water potential \jf is equal to 'l's· Thus, the
\jf of the right arm is -0.23 MPa, whereas the \jf of the left arm
(pure water) is 0 MPa. Because water moves from regions of
higher water potential to regions of lower water potential, the
net water movement will be from the left arm of the tube to
{c)
{d)
t pressure
0.1 M
solution
t
Negative
pressure
(ten~ion)
Pure
__._
H20 ---.
+ - H20
~
+ - H20
H20
'l'p =0
'l's =0
'Jf =0 MPa
'l'p = 0
'l's = -0.23
'Jf = -0.23 MPa
'l'p =0
'l's =0
'Jf = 0 MPa
.A Figure 36.8 Water potential and
water movement: an artificial model.
Net movement is from higher 'Jf to lower 'l'· In
this model, a membrane (dashed line) separates
pure water from a 0.1 M solution, so 'l's is 0 in
'l'p = 0.23
'l's = -0.23
'Jf = 0 MPa
'l'p = 0
'l's = 0
'Jf = 0 MPa
'l'p = 0.30
'l's = -0.23
'Jf = 0.07 MPa
the left arm and - 0.23 in the right. The values
of 'Jf are before net movement. {a) If no
pressure is applied, 'Jfs determines net
movement. (b) Positive pressure can raise 'Jf by
increasing 'Jfp, here making 'Jf the same in both
CHAPTER THIRTY-SIX
'l'p = -0.30
'l's = 0
'Jf = -0.30 MPa
'l'p = 0
'l's = -0.23
'J1 = -0.23 MPa
arms, so there is no net movement. (c) Raising
'Jf further on the right by positive pressure
causes net movement to the left. (d) Negative
pressure reduces 'Jfp. In this case, it causes net
movement to the left by reducing 'Jf there .
Resource Acquisition and Transport in Vascular Plants
769
water potential of the extracellular environment: in this example,
0 MPa. A dynamic equilibrium has been reached, and there is no
further net movement of water.
In contrast to a flaccid cell, a walled cell with a greater solute
concentration than its surroundings is turgid, or very firm.
When turgid cells in a nonwoody tissue push against each
other, the tissue is stiffened. The effects of turgor loss are seen
during wilting, when leaves and stems droop as a result of
cells losing water (Figure 36.10).
the right arm, as shown in Figure 36.8a. But applying a positive
physical pressure of +0.23 MPa to the solution in the right arm
raises its water potential from a negative value to 0 MPa (\jf =
- 0.23 + 0.23). As shown in Figure 36.8b, there is now no net
flow of water between this pressurized solution and the compartment of pure water. If we increase \jfp to +0.30 MPa in the
right arm, as in Figure 36.8c, then the solution has a water potential of +0.07 MPa (\jf = -0.23 + 0.30), and this solution will
actually lose water to a compartment containing pure water.
Whereas applying positive pressure increases \jf, applying negative pressure (tension) reduces \jf, as shown in Figure 36.8d. In
this case, a negative pressure potential of - 0.30 MPa reduces
the \jf of the water compartment enough so that water is drawn
from the solution on the right side.
Now let's consider how water potential affects absorption
and loss of water by a living plant cell. First, imagine a cell that
is flaccid (limp) as a result of losing water. The cell has a \jfp of
0 MPa. Suppose this flaccid cell is bathed in a solution of higher
solute concentration (more negative solute potential) than the
cell itself (Figure 36.9a). Since the external solution has the lower
(more negative) water potential, water diffuses out of the cell.
The cell's protoplast undergoes plasmolysis-that is, it shrinks
and pulls away from the cell wall. If we place the same flaccid cell
in pure water (\jf = 0 MPa) (Figure 36.9b), the cell, because it
contains solutes, has a lower water potential than the water, and
water enters the cell by osmosis. The contents of the cell begin
to swell and press the plasma membrane against the cell wall.
The partially elastic wall, exerting turgor pressure, pushes back
against the pressurized protoplast. When this pressure is enough
to offset the tendency for water to enter because of the solutes in
the cell, then \jfp and \jfs are equal, and \jf = 0. This matches the
A Figure 36.10 A wilted Impatiens plant regains its
turgor when watered.
Initial flaccid cell:
\jlp =
0
o/s = - 0.7
0.4 M sucrose solution:
\jlp
o/s
=
0
\jl
=-0.7 MPa
\jlp
= -0.9
o/s
'I'
'I' = -0.9 MPa
=
=-0.9 MPa
(a) Initial conditions: cellular \jl > environmental \jl. The cell
loses water and plasmolyzes . After plasmolysis is complete, the
water potentials of the cell and its surroundings are the same.
u N 1r s 1x
Turgid cell
at osmotic equilibrium
with its surroundings
'If = 0 MPa
(b) Initial conditions: cellular \jl < environmental \jl. There is a
net uptake of water by osmosis, causing the cell to become
turgid . When this tendency for water to enter is offset by the
back pressure of the elastic wall, water potentials are equal for
the cell and its surroundings. (The volume change of the cell is
exaggerated in this diagram .)
A Figure 36.9 Water relations in plant cells. In these experiments, identical cells, initially
flacc id, are placed in two environments. (Protoplasts of flaccid cells are in contact with their walls
but lack turgor pressure .) Blue arrows indicate initial net water movement.
770
=0 MPa
\jlp = 0.7
o/s = -0 .7
0
o/s = -0.9
'If
=0
=0
~
-=:::1;
Plasmolyzed cell
at osmotic equilibrium
with its surroundings
\jlp
Pure water:
Plant Form and Function
•
•
route, water and solutes move out of one cell, across the cell
wall, and into the neighboring cell, which may pass them to the
next cell in the same way. The transmembrane route requires
repeated crossings of plasma membranes as water and solutes
exit one cell and enter the next. Substances may use more than
one route. Scientists are debating which route, if any, is responsible for the most transport.
Aquaporins: Facilitating Diffusion of Water
A difference in water potential determines the direction of water movement across membranes, but how do water molecules actually cross the membranes? Water molecules are
small enough to diffuse across the phospholipid bilayer, even
though the middle zone is hydrophobic (see Figure 7.2), but
their movement is too rapid to be explained by unaided diffusion. Indeed, transport proteins called aquaporins facilitate
the diffusion (see Chapter 7). These selective channels, which
have been found most commonly in plants, affect the rate at
which water diffuses down its water potential gradient. Evidence is accumulating that the rate of water movement
through these proteins is regulated by phosphorylation of the
aquaporin proteins, which can be induced by increases in cytoplasmic calcium ions or decreases in cytoplasmic pH. Recent evidence suggests that aquaporins may also facilitate
absorption of C0 2 by plant cells.
Bulk Flow in Long-Distance Transport
Diffusion and active transport are fairly efficient for shortdistance transport within a cell and between cells. However,
these processes are much too slow to function in long-distance
transport within a plant. Although diffusion from one end of
a cell to the other takes just seconds, diffusion from the roots
to the top of a giant redwood would take decades or longer. Instead, long-distance transport occurs through bulk flow, the
movement of a fluid driven by pressure.
Within tracheids and vessel elements of the xylem and within
the sieve-tube elements (also called sieve-tube members) of the
phloem, water and dissolved solutes move together in the same
direction by bulk flow. The structures of these conducting cells
of the xylem and phloem help to mal<e bulk flow possible. If you
have ever dealt with a partially clogged drain, you know that the
volume of flow depends on the pipe's diameter. Clogs reduce the
effective diameter of the drainpipe. Such experiences help us
Three Major Pathways ofTran sport
Transport within plants is also regulated by the compartmental
structure of plant cells (Figure 36.11 a). Outside the protoplast
is a cell wall (see Figures 6.9 and 6.28), consisting of a mesh of
polysaccharides through which mineral ions diffuse readily.
Because every plant cell is separated from its neighboring
cells by cell walls, ions can diffuse across a tissue (or be carried passively by water flow) entirely
through the apoplast (Figure 36.11b),
Transport proteins in
Transport proteins in
the continuum formed by cell walls, exthe plasma membrane
the vacuolar
tracellular spaces, and the dead interiors
1 _1_ 1 1 :
-, membrane regulate
regulate traffic of 1
.
•
1 1
molecules between
traffic of molecules
of tracheids and vessels. However, it is the
between the cytosol
the cytosol and the
plasma membrane that directly controls
and the vacuole.
cell wall.
the traffic of molecules into and out of the
protoplast. Just as the cell walls form a
Plasmodesma
Vacuolar membrane
continuum, so does the cytosol of cells,
Plasma membrane
collectively referred to as the symplast
(a) Cell compartments. The cell wall, cytosol, and vacuole are the three main
(see Figure 36.11b). The cytoplasmic
compartments of most mature plant cells .
channels called plasmodesmata conKey
nect the cytoplasm of neighboring cells.
The compartmental structure of plant
Apoplast
cells provides three routes for shortTransmembrane route
Symplast
distance transport within a plant tissue
or organ: the apoplastic, symplastic, and
The symplast is the
~
continuum of
transmembrane routes (see Figure 36.11b).
The apoplast is
cytosol connected
.,.
In the apoplastic route, water and solutes
the continuum
by plasmodesmata.
move along the continuum of cell walls and
of cell walls and
extracellular
extracellular spaces. In the symplastic
Symplastic route
1 '
'
1
spaces.
route, water and solutes move along the
' route
Apoplastic
continuum of cytosol within a plant tissue.
(b) Transport routes between cells. At the tissue level, there are three pathways:
This route requires only one crossing of a
the transmembrane, symplastic, and apoplastic routes . Substances can transfer
plasma membrane. After entering one cell,
from one pathway to another.
substances can move from cell to cell via
.A. Figure 36.11 Cell compartments and routes for short-distance transport.
plasmodesmata. In the transmembrane
1
I
I_
~
CHAPTER THIRTY-SIX
m~
Resource Acquisition and Transport in Vascular Plants
771
understand how the structures of plant cells specialized for
bull< flow fit their function. As you learned in Chapter 35, mature tracheids and vessel elements are dead cells and therefore
have no cytoplasm, and the cytoplasm of sieve-tube elements
is almost devoid of internal organelles (see Figure 35.10). Like
unplugging a kitchen drain, loss of cytoplasm in a plant's
uplumbing" allows for efficient bulk flow through the xylem
and phloem. Bull< flow is also enhanced by the perforation
plates at the ends of vessel elements and the porous sieve plates
connecting sieve-tube elements.
Diffusion, active transport, and bulk flow act in concert to
transport resources throughout the whole plant. For example,
bulk flow due to a pressure difference is the mechanism of
long-distance transport of sugars in the phloem, but active
transport of sugar at the cellular level maintains this pressure
difference. In the next three sections, we'll examine in more
detail the transport of water and minerals from roots to
shoots, the control of evaporation, and the transport of sugars.
CONCEPT
CHECK
36.2
1. If a plant cell immersed in distilled water has a \jfs of
-0.7 MPa and a \jf of 0 MPa, what is the cell's \jfp? If
you put it in an open beaker of solution that has a \jf
of -0.4 MPa, what would be its \jfp at equilibrium?
2. How would an aquaporin deficiency affect a plant
cell's ability to adjust to new osmotic conditions?
3. How would the long-distance transport of water be
affected if vessel elements and tracheids were alive at
maturity? Explain.
4. Mfh:t·SIIM What would happen if you put plant
protoplasts in pure water? Explain.
For suggested answers, see Appendix A
C 0 N C E P T
36 •3
nd minerals are
transported from roots to shoots
Picture yourself struggling to carry a very large container of water up several flights of stairs. Then consider the fact that water
within a plant is transported effortlessly against the force of
gravity. Up to 800 L (800 kg or 1,760 lb) of water reach the top
of an average-sized tree every day. But trees and other plants
have no pumping mechanism. So how is this feat accomplished?
To answer this question, we'll follow each step in the journey of
water and minerals from the tips of roots to the tips of shoots.
Absorption of Water and Minerals
by Root Cells
Although all living plant cells absorb nutrients across their
plasma membranes, the cells near the tips of roots are partie772
UNIT SIX
Plant Form and Function
ularly important because most of the water and mineral absorption occurs there. In this region, the epidermal cells are
permeable to water, and many are differentiated into root
hairs, modified cells that account for much of the absorption
of water by roots (see Figure 35.3). The root hairs absorb the
soil solution, which consists of water molecules and dissolved
mineral ions that are not bound tightly to soil particles. The
soil solution flows into the hydrophilic walls of epidermal cells
and passes freely along the cell walls and the extracellular
spaces into the root cortex. This flow enhances the exposure
of the cells of the cortex to the soil solution, providing a much
greater membrane surface area for absorption than the surface area of the epidermis alone. Although the soil solution
usually has a low mineral concentration, active transport enabies roots to accumulate essential minerals, such as K+, to
concentrations hundreds of times higher than in the soil.
TransJ?ort of Water and Minerals
into the Xylem
Water and minerals that pass from the soil into the root cortex
cannot be transported to the rest of the plant until they enter the
xylem of the stele, or vascular cylinder. The endodermis, the innermost layer of cells in the root cortex, surrounds the stele and
functions as a last checkpoint for the selective passage of minerals from the cortex into the vascular tissue (Figure 36.12). Minerals already in the symplast when they reach the endodermis
continue through the plasmodesmata of endodermal cells and
pass into the stele. These minerals were already screened by the
plasma membrane they had to cross to enter the symplast in the
epidermis or cortex. Those minerals that reach the endodermis
via the apoplast encounter a dead end that blocks their passage
into the stele. This barrier, located in the transverse and radial
walls of each endodermal cell, is the Casparian strip, a belt made
of suberin, a waxy material impervious to water and dissolved
minerals (see Figure 36.12). Thus, water and minerals cannot
cross the endodermis and enter the vascular tissue via the
apoplast. The Casparian strip forces water and minerals that are
passively moving through the apoplast to cross the plasma membrane of an endodermal cell and enter the stele via the symplast.
The endodermis, with its Casparian strip, ensures that no
minerals can reach the vascular tissue of the root without
crossing a selectively permeable plasma membrane. The endodermis also prevents solutes that have accumulated in the
xylem from leaking back into the soil solution. The structure
of the endodermis and its strategic location fit its function as
an apoplastic barrier between the cortex and the stele. The endodermis helps roots to transport certain minerals preferentially from the soil into the xylem.
The last segment in the soil-to-xylem pathway is the passage
of water and minerals into the tracheids and vessel elements of
the xylem. These water-conducting cells lack protoplasts when
mature and therefore are part of the apoplast. Endodermal
cells, as well as living cells within the stele, discharge minerals
How does the Casparian strip force water and minerals to
IJ pass
through the plasma membranes of endodermal cells?
Pathway
through
symplast
0
J
•
Casparian strip
"' Figure 36.12 Transport of water and minerals
from root hairs to the xylem.
~
,~
Apoplastic route. Uptake
of soil solution by the
hydrophilic walls of root hairs
provides access to the apoplast.
Water and minerals can then
diffuse into the cortex along
this matrix of walls.
f) Symplastic route.
Minerals
and water that cross the
plasma membranes of root
hairs can enter the symplast.
8
0
Transmembrane route. As
soil solution moves along the
apoplast, some water and
minerals are transported into
the protoplasts of cells of the
epidermis and cortex and then
move inward via the symplast.
'--v----1 '----v---l
Epidermis
Endodermis
Stele
'-----------..,......-------__/ (vascular
Cortex
cylinder)
The endoderm is: controlled entry to the stele. Within the transverse and
radial walls of each endodermal cell is the Casparian strip, a belt of waxy
material (purple band) that blocks the passage of water and dissolved minerals.
Only minerals already in the symplast or entering that pathway by crossing the
plasma membrane of an endodermal cell can detour around the Casparian strip
and pass into the stele, the vascular cylinder.
from their protoplasts into their own cell walls. Both diffusion
and active transport are involved in this transfer of solutes from
symplast to apoplast, and the water and minerals are now free
to enter the tracheids and vessels, where they are transported
to the shoot system by bulk flow.
Bulk Flow Driven by Negative Pressure
in the Xylem
Water and minerals from the soil enter the plant through the
epidermis of roots, cross the root cortex, and pass into the
stele. From there the xylem sap, the water and dissolved minerals in the xylem, gets transported long distances by bulk
flow to the veins that branch throughout each leaf.
As noted earlier, bull< flow is much faster than diffusion or active transport. Peak velocities in the transport of xylem sap can
range from 15 to 45 m/hr for trees with wide vessels. Leaves depend on this efficient delivery system for their supply of water.
Plants lose an astonishing amount of water by transpiration, the
loss of water vapor from leaves and other aerial parts of the plant.
Consider the example of maize (commonly called corn in the
0
Transport in the xylem. Endodermal cells and also
living cells within the stele discharge water and
minerals into their walls (apoplast). The xylem vessels
then transport the water and minerals upward into the
shoot system .
United States). A single planttranspires 60 L (60 kg) of water during a growing season. A maize crop growing at a typical density
of 60,000 plants per hectare transpires almost 4 million L of water per hectare every growing season (about 400,000 gallons of
water per acre per growing season). Unless the transpired water
is replaced by water transported up from the roots, the leaves will
wilt, and the plants will eventually die. The flow of xylem sap also
brings mineral nutrients to the shoot system.
Xylem sap rises to heights of more than 100m in the tallest
trees. Is the sap mainly pushed upward from the roots, or is it
mainly pulled upward by the leaves? Let's evaluate the relative
contributions of these two mechanisms.
Pushing Xylem Sap: Root Pressure
At night, when there is almost no transpiration, root cells continue pumping mineral ions into the xylem of the stele. Meanwhile, the endodermis helps prevent the ions from leaking
out. The resulting accumulation of minerals lowers the water
potential within the stele. Water flows in from the root cortex,
generating root pressure, a push of xylem sap. The root pressure
CHAPTER THIRTY-SIX
Resource Acquisition and Transport in Vascular Plants
773
Pulling Xylem Sap: The Transpiration-CohesionTension Mechanism
Material can be moved upward by positive pressure from below or negative pressure from above. Here we'll focus on how
water is pulled by negative pressure potential in the xylem. As
we investigate this mechanism of transport, we'll see that
transpiration provides the pull and that the cohesion of water
due to hydrogen bonding transmits the pull along the entire
length of the xylem to the roots.
Stomata on a leaf's surface lead to a
maze of internal air spaces that expose the mesophyll cells to
the C0 2 they need for photosynthesis. The air in these spaces
is saturated with water vapor because it is in contact with the
moist walls of the cells. On most days, the air outside the leaf
is drier; that is, it has a lower water potential than the air inside
the leaf. Therefore, water vapor in the air spaces of a leaf diffuses down its water potential gradient and exits the leaf via
the stomata. It is this loss of water vapor from the leaf by diffusion and evaporation that we call transpiration.
But how does loss of water vapor from the leaf translate into
a pulling force for upward movement of water through a plant?
The negative pressure potential that causes water to move up
through the xylem develops at the surface of mesophyll cell walls
in the leaf (Figure 36.14). The cell wall acts like a very fine capillary network. Water adheres to the cellulose microfibrils and
other hydrophilic components of the cell wall. As water evaporates from the water film that covers the cell walls of mesophyll
cells, the air-water interface retreats farther into the cell wall.
Because of the high surface tension of water, the curvature of the
Transpirational Pull
A Figure 36.13 Guttation. Root pressure is forcing excess water
from this strawberry leaf.
sometimes causes more water to enter the leaves than is transpired, resulting in guttation, the exudation of water droplets
that can be seen in the morning on the tips or edges of some plant
leaves (Figure 36.13). Guttation fluid should not be confused
with dew, which is condensed atmospheric moisture.
In most plants, root pressure is a minor mechanism driving
the ascent of xylem sap, at most pushing water only a few meters. The positive pressures produced are simply too weak to
overcome the gravitational force of the water column in the
xylem, particularly in tall plants. Many plants do not generate
any root pressure. Even in plants that display guttation, root
pressure cannot keep pace with transpiration after sunrise. For
the most part, xylem sap is not pushed from below by root
pressure but pulled by the leaves themselves.
0
Water from the xylem is pulled into
the surrounding cells and air spaces to
replace the water that was lost.
Upper
epiderm is - -
0
The increased surface tension
shown in step 8 pulls water from
surrounding cells and air spaces.
8
The evaporation of the water film causes the
air-water interface to retreat farther into the cell wall
and to become more curved. This curvature increases
the surface tension and the rate of transpiration.
Mesophyll
f) At first, the water vapor lost by transpiration is
replaced by evaporation from the water film that
coats mesophyll cells.
0
In transpiration, water vapor (shown as blue dots)
diffuses from the moist air spaces of the leaf to the
drier air outside via stomata .
Microfibril
Water 'Air-water
interface
(cross section) film
A Figure 36.14 Generation of transpirational pull. Negative pressure (tension) at the airwater interface in the leaf is the basis of transpirational pull, which draws water out of the xylem .
774
UNIT SIX
Plant Form and Function
•
•
interface induces a tension, or negative pressure potential, in the
water. As more water evaporates from the cell wall, the curvature
of the air-water interface increases and the pressure of the water
becomes more negative. Water molecules from the more hydrated parts of the leaf are then pulled toward this area to reduce
the tension. These pulling forces are transferred to the xylem because each water molecule is cohesively bound to the next by hydrogen bonds. Thus, transpirational pull depends on several of
the properties of water discussed in Chapter 3: adhesion, cohesion, and surface tension.
The role of negative pressure potential in transpiration is
consistent with the water potential equation because negative
pressure potential (tension) lowers water
potential (see Figure 36.8d). Because water moves from areas of higher water potential to areas of lower water potential,
Outside air \V
the more negative pressure potential at
= -100.0 MPa
the air-water interface causes water in
xylem cells to be ~~pulled" into mesophyll
Leaf \V (air spaces)
cells, which lose water to the air spaces,
= - 7.0 MPa
where it diffuses out through stomata. In
Leaf \V (cell walls)
this way, the negative water potential of
= - 1.0 MPa
leaves provides the ~~pull" in transpirational pull.
sion, their thick secondary walls prevent them from collapsing,
much as wire rings maintain the shape of a vacuum-cleaner
hose. The tension produced by transpirational pull lowers water potential in the root xylem to such an extent that water flows
passively from the soil, across the root cortex, and into the stele.
Transpirational pull can extend down to the roots only
through an unbroken chain of water molecules. Cavitation, the
formation of a water vapor pocket, breal<s the chain. It is more
common in wide vessels than in tracheids and can occur during
drought stress or when xylem sap freezes in winter. The air bubbles resulting from cavitation expand and block water channels
of the xylem. The rapid expansion of air bubbles produces
Cohesion and Adhesion in the Ascent
of Xylem Sap The transpirational pull
~
on xylem sap is transmitted all the way
from the leaves to the root tips and even
into the soil solution (Figure 36.15). Cohesion and adhesion facilitate this longdistance transport by bulk flow. The
cohesion of water due to hydrogen bonding makes it possible to pull a column of
xylem sap from above without the water
molecules separating. Water molecules
exiting the xylem in the leaf tug on adjacent water molecules, and this pull is relayed, molecule by molecule, down the
entire column of water in the xylem.
Meanwhile, the strong adhesion of water
molecules (again by hydrogen bonds) to
the hydrophilic walls of xylem cells helps
offset the downward force of gravity.
The upward pull on the sap creates
tension within the xylem vessels and tracheids, which are like elastic pipes. Positive pressure causes an elastic pipe to
swell, whereas tension pulls the walls of
the pipe inward. On a warm day, a decrease in the diameter of a tree trunk can
even be measured. As transpirational pull
puts the vessels and tracheids under ten-
Trunk xylem \V
= -0.8 MPa
Trunk xylem \V
= - 0.6 MPa
Soil \V
= -0.3 MPa
A Figure 36.15 Ascent of xylem sap. Hydrogen bonding forms an unbroken chain of water
molecules extending from leaves to the soil. The force driving the ascent of xylem sap is a gradient
of water potential ('If). For bulk flow over long distance, the 'I' gradient is due mainly to a gradient
of the pressure potential ('Jfp) . Transpiration results in the 'Jfp at the leaf end of the xylem being
lower than the 'Jfp at the root end. The 'I' values shown at the left are a snapshot. During
daylight, they may vary, but the direction of the 'I' gradient remains the same.
II
-
.OJS.Ci.-
II
~
iof.li1c
Visit
www.campbellbiology.com
for the BioFiix 3-D Animation on
Water Transport in Plants.
CHAPTER THIRTY-SIX
Resource Acquisition and Transport in Vascular Plants
775
clicking noises that can be heard by placing sensitive microphones at the surface of the stem.
Root pressure enables small plants to refill blocked vessels
in spring. In trees, though, root pressure is insufficient to push
water to the top, so a vessel with a water vapor pocket usually
cannot function in xylem sap transport. However, the chain of
molecules can detour around the pocket through pits between
adjacent tracheids or vessels. In addition, secondary growth
adds a layer of new xylem each year. Only the youngest, outermost secondary xylem transports water. Although the older
secondary xylem no longer transports water, it does provide
support for the tree (see Figure 35.22).
Xylem Sap Ascent by Bulk Flow: A Review
The transpiration-cohesion-tension mechanism that transports xylem sap against gravity is an excellent example of how
physical principles apply to biological processes. In the longdistance transport of water from roots to leaves by bulk flow,
the movement of fluid is driven by a water potential difference
at opposite ends of xylem tissue. The water potential difference is created at the leaf end of the xylem by the evaporation
of water from leaf cells. Evaporation lowers the water potential at the air-water interface, thereby generating the negative
pressure (tension) that pulls water through the xylem.
Bulk flow in the xylem differs from diffusion in some key
ways. First, it is driven by differences in pressure potential
(\jfp); solute potential (\jfs) is not a factor. Therefore, the water
potential gradient within the xylem is essentially a pressure
gradient. Also, the flow does not occur across plasma membranes of living cells, but instead within hollow, dead cells.
Furthermore, it moves the entire solution together-not just
water or solutes-and at much greater speed than diffusion.
The plant expends no energy to lift xylem sap by bulk flow. Instead, the absorption of sunlight drives most of transpiration by
causing water to evaporate from the moist walls of mesophyll
cells and by lowering the water potential in the air spaces within
a leaf. Thus, the ascent of xylem sap is ultimately solar powered.
CONCEPT
CHECK
C 0 N C E P T
36.4
help regulate the rate
of transpiration
Leaves generally have large surface areas and high surface-tovolume ratios. The large surface area enhances light absorption
for photosynthesis. The high surface-to-volume ratio aids in
C0 2 absorption during photosynthesis as well as in the release
of 0 2 as a by-product of photosynthesis. Upon diffusing
through the stomata, C02 enters a honeycomb of air spaces
formed by the spongy mesophyll cells (see Figure 35.18). Because of the irregular shapes of these cells, the leaf's internal
surface area may be 10 to 30 times greater than the external
surface area.
Although large surface areas and high surface-to-volume
ratios increase the rate of photosynthesis, they also increase
water loss by way of the stomata. Thus, a plant's tremendous
requirement for water is largely a negative consequence of the
shoot system's need for ample gas exchange for photosynthesis. By opening and closing the stomata, guard cells help balance the plant's requirement to conserve water with its
requirement for photosynthesis (Figure 36.16) .
Stomata: Major Pathways for Water Loss
About 95% of the water a plant loses escapes through stomata,
although these pores account for only 1-2% of the external
leaf surface. The waxy cuticle limits water loss through theremaining surface of the leaf. Each stoma is flanked by a pair of
guard cells. Guard cells control the diameter of the stoma by
changing shape, thereby widening or narrowing the gap between the guard cell pair. Under the same environmental conditions, the amount of water lost by a leaf depends largely on
the number of stomata and the average size of their pores.
The stomatal density of a leaf, which may be as high as
20,000 per square centimeter, is under both genetic and environmental controL For example, as a result of evolution by
36.3
1. How do xylem cells facilitate long-distance transport?
2. A horticulturalist notices that when Zinnia flowers are
cut at dawn, a small drop of water collects at the surface of the stump. However, when the flowers are cut
at noon, no drop is observed. Suggest an explanation.
3. A scientist adds a water-soluble inhibitor of photosynthesis to a plant's roots, but photosynthesis is not
reduced. Why?
4. Mftlj:t.sl!g Suppose anArabidopsis mutant lacking
functional aquaporins has a root mass three times greater
than that of wild-type plants. Suggest an explanation.
For suggested answers, see Appendix A.
A Figure 36.16 An open stoma (left) and closed stoma (LMs).
776
UNIT
s1x
Plant Form and Function
J
-
•
•
,
natural selection, desert plants have lower stomatal densities
than do marsh plants. Stomatal density, however, is a developmentally plastic feature of many plants. High light exposures
and low C0 2 levels during leaf development lead to increased
density in many species. By measuring stomatal density of leaf
fossils, scientists have gained insight into the levels of atmospheric C0 2 in past climates. A recent British survey found
that stomatal density of many woodland species has decreased
since 1927, when a similar survey was made. This survey is
consistent with other findings that atmospheric C0 2 levels increased dramatically during the 1900s.
Mechanisms of Stomatal Opening and Closing
When guard cells take in water from neighboring cells by osmosis, they become more turgid. In most angiosperm species,
the cell walls of guard cells are uneven in thickness, and the
cellulose microfibrils are oriented in a direction that causes
the guard cells to bow outward when turgid (Figure 36.17a) .
This bowing outward increases the size of the pore between
the guard cells. When the cells lose water and become flaccid,
they become less bowed, and the pore closes.
The changes in turgor pressure in guard cells result primarily from the reversible absorption and loss of K+. Stomata
open when guard cells actively accumulate K+ from neighboring epidermal cells (Figure 36.17b) . The flow of K+ across
the plasma membrane of the guard cell is coupled to the generation of a membrane potential by proton pumps. Stomatal
opening correlates with active transport of H+ out of the
guard cell. The resulting voltage (membrane potential) drives
K+ into the cell through specific membrane channels (see
Figure 36.7a). The absorption ofK+ causes the water potential
to become more negative within the guard cells, and the cells
become more turgid as water enters by osmosis. Because most
of the K+ and water are stored in the vacuole, the vacuolar
membrane also plays a role in regulating guard cell dynamics.
Stomatal closing results from a loss of K+ from guard cells to
neighboring cells, which leads to an osmotic loss of water.
Aquaporins also help regulate the osmotic swelling and
shrinking of guard cells.
Stimuli for Stomatal Opening and Closing
In general, stomata are open during the day and closed at
night, preventing the plant from losing water under conditions when photosynthesis cannot occur. At least three cues
contribute to stomatal opening at dawn: light, C0 2 depletion,
and an internal "clock" in guard cells.
The light stimulates guard cells to accumulate K+ and become turgid. This response is triggered by illumination of
blue-light receptors in the plasma membrane of guard cells.
Activation of these receptors stimulates the activity of proton
pumps in the plasma membrane of the guard cells, in turn promoting absorption of K+.
Guard cells turgid/Stoma open
Guard cells flaccid/Stoma closed
Radially oriented
cellulose microfibrils
Cell
wall
(a} Changes in guard cell shape and stomatal opening and closing
(surface view}. Guard cells of a typical angiosperm are illustrated in
their turgid (stoma open) and flaccid (stoma closed) states. The radial
• orientation of cellulose microfibrils in the cell walls causes the guard
cells to increase more in length than width when turgor increases.
Since the two guard cells are tightly joined at their tips, they bow
outward when turgid, causing the stomatal pore to open .
H20 •
H20
....
..
(b) Role of potassium in stomatal opening and closing. The transport of K+ (potassium ions, symbolized here as red dots) across the
plasma membrane and vacuolar membrane causes the turgor
changes of guard cells. The uptake of anions, such as malate and
chloride ions (not shown), also contributes to guard cell swelling.
A Figure 36.17 Mechanisms of stomatal opening
and closing.
The stomata also open in response to depletion of C0 2
within the leaf's air spaces as a result of photosynthesis. As
C0 2 concentrations decrease during the day, the stomata progressively open if sufficient water is supplied to the leaf.
A third cue, the internal "clock" in the guard cells, ensures
that stomata continue their daily rhythm of opening and closing. This rhythm occurs even if a plant is kept in a dark location. All eukaryotic organisms have internal clocks that
regulate cyclic processes. Cycles with intervals of approximately 24 hours are called circadian rhythms, which you'll
learn more about in Chapter 39.
Environmental stresses, such as droughts, can cause stomata
to close during the daytime. When the plant has a water deficiency, guard cells may lose turgor and close stomata. In addition, a hormone called abscisic acid, produced in roots and
leaves in response to water deficiency, signals guard cells to
CHAPTER THIRTY-SIX
Resource Acquisition and Transport in Vascular Plants
777
close stomata. This response reduces wilting but also restricts
C0 2 absorption, thereby slowing photosynthesis. Since turgor
is necessary for cell elongation, growth ceases. These are some
reasons why droughts reduce crop yields.
Guard cells control the photosynthesis-transpiration compromise on a moment-to-moment basis by integrating a variety of internal and external stimuli. Even the passage of a cloud
or a transient shaft of sunlight through a forest can affect the
rate of transpiration.
Effects of Transpiration on Wilting
and Leaf Temperature
As long as most stomata remain open, transpiration is greatest on a day that is sunny, warm, dry, and windy because these
environmental factors increase evaporation. If transpiration
cannot pull sufficient water to the leaves, the shoot becomes
slightly wilted as cells lose turgor pressure (see Figure 36.10).
Although plants respond to such mild drought stress by rapidly closing stomata, some evaporative water loss still occurs
through the cuticle. Under prolonged drought conditions,
leaves can become severely wilted and irreversibly injured.
Transpiration also results in evaporative cooling, which can
lower a leaf's temperature by as much as 10oC compared with
the surrounding air. This cooling prevents the leaf from reaching temperatures that could denature enzymes involved in
photosynthesis and other metabolic processes.
Adaptations That Reduce Evaporative
Water Loss
Plants that are adapted to deserts and other regions with little
moisture are called xerophytes (from the Greek xero, dry).
The stone plants in Figure 36.1 are an example. Figure 36.18
T Figure 36.18 Some xerophytic adaptations.
T Oleander (Nerium oleander), shown in the inset, is commonly found
• Ocotillo (Fouquieria
splendens) is common in
the southwestern region
of the United States and
northern Mexico. It is
leafless during most of
the year, thereby avoiding
excessive water loss
(right). Immediately after
a heavy rainfall , it
produces small leaves
(below and inset). As the
soil dries, the leaves
quickly shrivel and die .
in arid climates . Its leaves have a thick cuticle and multiple-layered
epidermal t issue that reduce water loss. Stomata are recessed in
cavities called "crypts," an adaptation that reduces the rate of
transpiration by protecting the stomata from hot, dry wind.
Trichomes help minimize transpiration by breaking up the flow of
air, allowing the chamber of the crypt to have a higher humidity
than the surrounding atmosphere (LM).
Cuticle
Upper epidermal tissue
~I
Trichomes
("ha irs" )
• This is a close-up
view of stems of old
man cactus
(Cepha/ocereus
senilis), a Mexican
desert plant. The
long, white, hairlike
bristles help reflect
the sun .
778
UNIT SIX
Plant Form and Function
"'/ '
Crypt
Stomata
Lower epidermal
tissue
shows others. Rain comes infrequently in deserts, but when it
arrives the vegetation is transformed. Many species of desert
plants avoid drying out by completing their short life cycles
during the brief rainy seasons. Longer-lived species have unusual physiological or morphological adaptations that enable
them to withstand the harsh desert conditions. Xerophytes
are also found in other environments where access to liquid
fresh water is problematic, such as frozen regions and
seashores. Many xerophytes, such as cacti, have highly reduced leaves that resist excessive water loss; they carry out
photosynthesis mainly in their stems. The stems of many xerophytes are fleshy because they store water for use during
prolonged dry periods. Another adaptation to arid habitats is
crassulacean acid metabolism (CAM), a specialized form of
photosynthesis found in succulents of the family Crassulaceae and several other families (see Figure 10.20). Because
the leaves of CAM plants take in C0 2 at night, the stomata
can remain closed during the day, when evaporative stresses
are greater.
As we have seen, plants face a dilemma: how to acquire as
much C0 2 from the air as they can and at the same time retain
as much water as possible. Stomata are the most important
mediators of the conflicting demands of C0 2 acquisition and
water retention.
CONCEPT
CHECK
36.4
1. What are the stimuli that control the opening and
closing of stomata?
2. The pathogenic fungus Fusicoccum amygdali secretes a toxin called fusicoccin that activates the
plasma membrane proton pumps of plant cells and
leads to uncontrolled water loss. Suggest a mechanism by which the activation of proton pumps could
lead to severe wilting.
3. Mft!J:f.SIIM If you buy cut flowers, why might the
florist recommend cutting the stems underwater and
then transferring the flowers to a vase while the cut
ends are still wet?
For suggested answers, see Appendix A.
C 0 N C E P T
36 •5
re transported from
leaves and other sources
to sites of use or storage
You have read how water and minerals are absorbed by root
cells, transported through the endodermis, released into the
vessels and tracheids of the xylem, and carried to the tops of
plants by the bulk flow driven by transpiration. However,
transpiration cannot meet all the long-distance transport
needs of the plant. The flow of water and minerals from soil to
roots to leaves is largely in a direction opposite to the direction necessary for transporting sugars from mature leaves to
lower parts of the plants, such as root tips that require large
amounts of sugars for energy and growth. It is another tissue-the phloem-that transports the products of photosynthesis, a process called translocation.
Movement from Sugar Sources to Sugar Sinks
In angiosperms, the specialized cells that are conduits for
translocation are the sieve-tube elements. Arranged end to
end, they form long sieve tubes (see Figure 35.10). Between
these cells are sieve plates, structures that allow the flow of sap
along the sieve tube.
Phloem sap, the aqueous solution that flows through sieve
tubes, differs markedly from xylem sap. By far the most prevalent solute in phloem sap is sugar, typically sucrose in most
species. The sucrose concentration may be as high as 30% by
weight, giving the sap a syrupy thickness. Phloem sap may also
contain amino acids, hormones, and minerals.
In contrast to the unidirectional transport of xylem sap
from roots to leaves, phloem sap moves from sites of sugar
production to sites of sugar use or storage (see Figure 36.2). A
sugar source is a plant organ that is a net producer of sugar,
by photosynthesis or by breakdown of starch. A sugar sink is
an organ that is a net consumer or depository of sugar. Growing roots, buds, stems, and fruits are sugar sinks. Although expanding leaves are sugar sinks, fully grown leaves, if well
illuminated, are sugar sources. A storage organ, such as a tuber or a bulb, may be a source or a sink, depending on the season. When stockpiling carbohydrates in the summer, it is a
sugar sink. After breaking dormancy in the spring, it is a sugar
source because its starch is broken down to sugar, which is
carried to the growing shoot tips.
Sinks usually receive sugar from the nearest sugar sources.
The upper leaves on a branch, for example, may export sugar
to the growing shoot tip, whereas the lower leaves may export
sugar to the roots. A growing fruit may monopolize the sugar
sources that surround it. For each sieve tube, the direction of
transport depends on the locations of the sugar source and
sugar sink that are connected by that tube. Therefore, neighboring sieve tubes may carry sap in opposite directions if they
originate and end in different locations.
Sugar must be transported, or loaded, into sieve-tube elements before being exported to sugar sinks. In some species, it
moves from mesophyll cells to sieve-tube elements via the
symplast, passing through plasmodesmata. In other species, it
moves by symplastic and apoplastic pathways. In maize leaves,
for example, sucrose diffuses through the symplast from photosynthetic mesophyll cells into small veins. Much of it then
moves into the apoplast and is accumulated by nearby sievetube elements, either directly or through companion cells
CHAPTER THIRTY-SIX
Resource Acquisition and Transport in Vascular Plants
• .-.¥·
779
High H+ concentration
Cotransporter
Mesophyll cell
Cell walls (apoplast)
Plasma membrane
Key
Apoplast
Symplast
(b) A chemiosmotic mechanism is responsible for the
active transport of sucrose into companion cells and
sieve-tube elements. Proton pumps generate an H+
gradient, which drives sucrose accumulation with the
help of a cotransport protein that couples sucrose
transport to the diffusion of H+ back into the cell.
(a) Sucrose manufactured in mesophyll cells can travel via
the symplast (blue arrows) to sieve-tube elements . In
some species, sucrose exits the symplast near sieve
.& Figure 36.19
tubes and travels through the apoplast (red arrow). It is
Loading of sucrose
then actively accumulated from the apoplast by
into phloem.
sieve-tube elements and their companion cells.
\T
(Figure 36.19a). In some plants, the walls of the companion
cells feature many ingrowths, enhancing solute transfer between apoplast and symplast. Such modified cells are called
transfer cells (see Figure 29.5).
In many plants, sugar movement into the phloem requires
active transport because sucrose is more concentrated in
sieve-tube elements and companion cells than in mesophyll.
Proton pumping and cotransport enable sucrose to move
from mesophyll cells to sieve-tube elements (Figure 36.19b).
Sucrose is unloaded at the sink end of a sieve tube. The
process varies by species and organ. However, the concentration of free sugar in the sink is always lower than in the sieve
tube because the unloaded sugar is consumed during growth
and metabolism of the cells of the sink or converted to insoluble polymers such as starch. As a result of this sugar concentration gradient, sugar molecules diffuse from the phloem into
the sink tissues, and water follows by osmosis.
Bulk Flow by Positive Pressure: The Mechanism
ofTranslocation in Angiosperms
Phloem sap flows from source to sink at rates as great as 1 m/hr,
much faster than diffusion or cytoplasmic streaming, the circular flow of cytoplasm within cells. In studying angiosperms, researchers have concluded that phloem sap moves through a
sieve tube by bull< flow driven by positive pressure, known as
pressure flow (Figure 36.20). The building of pressure at the
source end and reduction of that pressure at the sink end cause
water to flow from source to sink, carrying the sugar along.
The pressure flow hypothesis explains why phloem sap flows
from source to sink, and experiments build a strong case for
pressure flow as the mechanism of translocation in angiosperms
(Figure 36.21). However, studies using electron microscopes
suggest that in nonflowering vascular plants, the pores between
phloem cells may be too small or obstructed to permit pressure
780
UNIT SIX
Plant Form and Function
Vessel
(xylem)
......
\
~ieve tub~
(phloem)
~ ~
~
~
~
~
~
0
~
~
H2o\1 ~. ~o ~
~ ~ ~ ~~
~~ ~ ~
~~. ~
8B
~
~
~
~
f) This uptake of water
generates a positive
pressure that forces
the sap to flow along
the tube .
~
I
~
8
The pressure is relieved
by the unloading of
sugar and the
consequent loss of
water at the sink.
0
In leaf-to-root
translocation, xylem
recycles water from
sink to source.
i
~·Et ~
0
H20jj
Loading of sugar (green
dots) into the sieve
tube at the source
reduces water potential
inside the sieve-tube
elements. Th is causes
the tube to take up
water by osmosis.
~
.& Figure 36.20 Bulk flow by positive pressure (pressure
flow) in a sieve tube.
flow. Thus, it is not known if the model applies to all other
vascular plants.
Sinks vary in energy demands and capacity to unload sugars. Sometimes there are more sinks than can be supported by
sources. In such cases, a plant might abort some flowers, seeds,
or fruits-a phenomenon called self-thinning. Removing sinks
can also be a horticulturally useful practice. For example, since
large apples command a much better price than small ones,
growers sometimes remove flowers or young fruits so that
their trees produce fewer but larger apples.
I•
In ui
C 0 N C E P T
Does phloem sap contain more sugar near
sources than sinks?
The pressure flow hypothesis predicts that
phloem sap near sources should have a higher sugar content than
phloem sap near sinks. To test this aspect of the hypothesis, S. Rogers
and A. J. Peel, at the University of Hull in England, used aphids that
feed on phloem sap. An aphid probes with a hypodermic-like
mouthpart called a stylet that penetrates a sieve-tube element.
As sieve-tube pressure forced out phloem into the stylets, the
researchers separated the aphids from the stylets, which then
acted as taps exuding sap for hours. Researchers measured the
sugar concentration of sap from stylets at different points
between a source and sink .
l
25
~m
36.6
plast is highly dynamic
Although we have been discussing transport in mostly physical terms, almost like the flow of solutions through pipes,
plant transport is a dynamic process. That is, the transport
needs of a plant cell typically change during its development.
A leaf, for example, may begin as a sugar sink but spend most
of its life as a sugar source. Also, environmental changes may
trigger marked responses in plant transport processes. Water
stress may activate signal transduction pathways that greatly
alter the membrane transport proteins governing the overall
transport of water and minerals. Because the symplast is living tissue, it is largely responsible for the dynamic changes in
plant transport processes.
Plasmodesmata: Continuously
Changing Structures
Stylet in sieve-tube
element
Separated stylet
exuding sap
The closer the stylet was to a sugar source, the
higher its sugar concentration was .
~USION I The results of such experiments support the
pressure flow hypothesis, which predicts that sugar concentrations should be higher in sieve tubes closer to sugar sources.
SOURCE
S. Rogers and A. J. Peel , Some evidence for the existence
of turgor pressure in the sieve tubes of willow (Salix), Planta 126, no.
3:259- 267 (1975).
Spittle bugs are xylem sap feeders that use strong
muscles to pump xylem sap through their guts . Could you isolate
xylem sap from the excised stylets of spittle bugs?
CONCEPT
CHECK
36.5
1. Compare and contrast the forces that move phloem
sap and xylem sap over long distance.
2. Identify plant organs that are sugar sources, organs that
are sugar sinks, and organs that might be either. Explain.
3. Why can xylem transport water and minerals using
dead cells, whereas phloem requires living cells?
4. Mftlllf·iliM Apple growers in Japan sometimes
make a nonlethal spiral slash around the bark of trees
destined for removal after the growing season. This
practice makes the apples sweeter. Why?
For suggested answers, see Appendix A.
Plasmodesmata provide an example of the dynamic nature of
the symplast. Biologists formerly thought of plasmodesmata as
unchanging pore-like structures, based mostly on the static images from electron microscopy. Recently, however, new techniques have revealed that plasmodesmata are highly dynamic
structures that can change in permeability and number. They
can open or close rapidly in response to changes in turgor pressure, cytoplasmic calcium levels, or cytoplasmic pH. Although
some form during cytokinesis, they can also form much later.
Moreover, loss of function is common during differentiation.
For example, as a leaf matures from a sink to a source, its plasmodesmata either close or are eliminated, causing phloem unloading to cease.
Early studies by plant physiologists and pathologists came
to differing conclusions regarding pore sizes of plasmodesmata. Physiologists injected fluorescent probes of different
molecular sizes into cells and recorded whether the molecules
passed into adjacent cells. Based on these observations, they
concluded that the pore sizes were approximately 2.5 nmtoo small for macromolecules such as proteins to pass. In contrast, pathologists provided electron micrographs showing
evidence of passage of viral particles with diameters of 10 nm
or greater. One hypothesis to explain these discordant findings was that viruses can greatly dilate plasmodesmata.
Subsequently, it was learned that plant viruses produce viral
movement proteins that do cause plasmodesmata to dilate, enabling viral RNA to pass between cells. More recent evidence
shows that plant cells themselves regulate plasmodesmata as
part of a dynamic communication network. Viruses subvert this
network by mimicking the cell's regulators of plasmodesmata.
A high degree of cytoplasmic interconnectedness exists only
within certain groups of cells and tissues, known as symplastic
domains. Informational molecules, such as proteins and RNAs,
coordinate development between cells within each symplastic
CHAPTER THIRTY-SIX
Resource Acquisition and Transport in Vascular Plants
781
domain. If symplastic communication is altered by mutation,
development can be grossly affected, as was shown by Patricia
Zambryski and colleagues at the University of California, Berkeley
(Figure 36.22). (See the interview on pages 736-737.)
Electrical Signaling in the Phloem
Rapid, long-distance electrical signaling through the phloem
is another dynamic feature of the symplast. Electrical signaling has been studied extensively in plants that have rapid leaf
movements, such as the sensitive plant (Mimosa pudica) and
Venus flytrap (Dionaea muscipula). However, its role in other
species is less clear. Some studies have revealed that a stimulus in one part of a plant can trigger an electrical signal in the
phloem that affects another part, such as eliciting a change in
gene transcription, respiration, photosynthesis, phloem unloading, or hormonal levels. Thus, the phloem can serve a
nerve-like function, allowing for swift electrical communication between widely separated organs.
Do alterations in symplastic communication
affect plant development?
EXPERIMENT
Patricia Zambryski and colleagues at the University
of California, Berkeley, loaded large and small fluorescent probes at
the base of the cotyledon and the root tip of developing Arabidopsis
embryos. Studies of wild-type embryos had revealed a period in the
middle of embryogenesis when symplastic transport of the large
probes ceased but transport of small probes continued. The researchers screened for mutants that still transported the large probes
during this period and then analyzed their growth into seedlings. The
light micrographs below contrast the movement of the large probes
(green fluorescence) in a wild-type embryo and mutant embryo.
Base of
cotyledon
Root tip
Phloem: An Information Superhighway
In addition to transporting sugars and conducting electrical
signals, the phloem is a "superhighway" for the systemic transport of macromolecules and viruses. Systemic changes are
those that spread throughout the body, affecting many or all of
the body's systems or organs. Macromolecules translocated
through the phloem include proteins and various types of RNA
that enter the sieve tubes through plasmodesmata. Although
plasmodesmata are often likened to the gap junctions between
animal cells, their ability to traffic proteins and RNA is unique.
Systemic communication through the phloem helps integrate the functions of the whole plant. One classic example is
the delivery of a flower-inducing signal from leaves to vegetative meristems. Another is a defensive response to localized
infection, in which signals traveling through the phloem activate defense genes in noninfected tissues.
The coordinated transport of materials and information is
central to plant survival. Plants acquire only so many resources in the course of their lifetimes. If these resources are
not distributed and used in an optimal manner, the plant will
not be able to compete well. Ultimately, the successful acquisition and conservation of resources and the integrated functioning of the whole plant are the most critical determinants
of whether the plant will compete successfully.
CONCEPT
CHECK
36.6
1. What factors influence symplastic communication?
2. How do plasmodesmata differ from gap junctions?
3. Mftll:t·JIIM If plants were genetically modified to be
unresponsive to viral movement proteins, would this
be a good way to prevent spread of infection? Explain.
For suggested answers, see Appendix A.
782
UNIT SIX
Plant Form and Function
SO
I ).!m
Mutant embryo
As shown in the scanning electron micrograph
on the left, about half of the cell files in the wild type consisted of
differentiated cells without root hairs (examples marked with yellow Xs) . The mutant seedlings were developmentally retarded,
with less cell differentiation than the wild-type seedlings. All cell
files in a mutant seedling's root epidermis developed root hairs
(examples marked with red circles).
I
I
SO
SO
).!m
).!m
Mutant seedling root tip
Isolation of the mutant and demonstration of
its altered development support the hypothesis that maintaining
symplastic domains is critical for proper plant development.
SOURCE
I. Kim, F. Hempel, K. Sha, J. Pfluger, and P. Zambryski,
Identification of a developmental transition in plasmodesmata! function during
embryogenesis in Arabidopsis thaliana, Development 125:1261-1272 (2002).
Suppose it was found that the mutation caused overproduction of an enzyme that cleaved the fluorescent molecule off
the large probe midway through embryogenesis. Would you interpret
the results differently?
I
•
l
MM§.Jf·M
Go to www.campbellbiology.com for BioFiix 3-D Animations,
MP3 Tutors, Videos, Practice Tests, an eBook, and more.
Transpiration lowers \jf in the leaf by producing a negative pressure
potential (tension). This low \jf draws water from the xylem. Cohesion and adhesion of water transmit the pulling force to the roots .
.,... Xylem Sap Ascent by Bulk Flow: A Review Transpiration
SUMMARY OF KEY CONCEPTS
CONCEPT
.,... Bulk Flow Driven by Negative Pressure in the Xylem
maintains movement of xylem sap against gravity.
MM§·lf.M
36.1
BioFlix 3-D Animation Water Transport in Plants
MP3 Tutor Transpiration
Activity Transport of Xylem Sap
land plants acquire resources both above and below
ground (pp. 764-767)
.,.. Shoot Architecture and
Light Capture
Arrangement and size of
leaves, branching, and
stem thickness help shoots
acquire C0 2 and light.
.,.. Root Architecture and
Acquisition of Water
and Minerals
Elongation, branching,
and mycorrhizae help
roots mine the soil for
water and minerals.
CONCEPT
36.2
CONCEPT
widen or narrow the diameter of stomatal pores. Genetic
and environmental factors influence stomatal density.
.,... Mechanisms of Stomatal Opening and Closing When
guard cells take up K+, they bow outward, widening the pore.
Stomatal closing involves the loss of K+.
.,... Stimuli for Stomatal Opening and Closing Stomatal
aperture is controlled by light, C0 2 , water availability, the
hormone abscisic acid, and circadian rhythm.
.,.. Effects of Transpiration on Wilting and Leaf Temperature
Transport occurs by short-distance diffusion or active
transport and by long-distance bulk flow (pp. 767-772)
.,.. Diffusion and Active Transport of Solutes Diffusion is the
spontaneous movement down concentration gradients.
Transport proteins aid diffusion across membranes. Proton
pumps generate an H + gradient used to transport solutes.
If water lost by transpiration is not replaced by absorption
from roots, the plant will wilt. Cooling by transpiration can
lower leaf temperature .
.,... Adaptations That Reduce Evaporative Water Loss
Reduced leaves and CAM photosynthesis are examples of
adaptations to arid environments.
MM§.Jf·M
.,.. Diffusion of Water (Osmosis) Osmosis is the spontaneous
movement of free water down its concentration gradient. Water flows across membranes from regions with higher water
potential (\j/) to regions with lower 'I'· Solutes decrease \jf.
Pressure may increase or decrease \jf.
.,... Three Major Pathways of Transport The symplast is the
cytoplasmic continuum linked by plasmodesmata. The
apoplast is the continuum of cell walls and extracellular
spaces.
Investigation How Is the Rate of Transpiration Calculated?
CONCEPT
36.5
Sugars are transported from leaves and other sources
to sites of use or storage (pp. 779-781)
.,.. Movement from Sugar Sources to Sugar Sinks Mature
leaves are the main sources, though storage organs can be seasonal sources. Meristems and developing fruits and seeds are
examples of sinks. Phloem loading and unloading depend on
active transport of sucrose. Sucrose is cotransported with H+,
which diffuses down a gradient generated by proton pumps .
.,... Bulk Flow in Long-Distance Transport Bulk flow is due to
pressure differences at opposite ends of vessel elements and
tracheids (for xylem sap) or sieve tubes (for phloem sap).
CONCEPT
36.4
Stomata help regulate the rate of transpiration
(pp. 776-779)
.,... Stomata: Major Pathways for Water Loss Guard cells
.,... Bulk Flow by Positive Pressure: The Mechanism of
Translocation in Angiosperms Loading of sugar at the
36.3
source and unloading at the sink maintain a pressure difference that keeps sap flowing through a sieve tube.
Water and minerals are transported from roots
to shoots (pp. 772-776)
.,... Absorption of Water and Minerals by Root Cells Root
MM§.JP.M
Activity Translocation of Phloem Sap
hairs and the extensive surface area of cortical cell membranes
enhance uptake of water and minerals.
.,... Transport of Water and Minerals into the Xylem Water
can cross the cortex via the symplast or apoplast, but min~rals
moving via the apoplast must finally cross the selective membranes of endodermal cells. The Casparian strip blocks
apoplastic transfer of minerals to the stele.
CONCEPT
36.6
The symplast is highly dynamic (pp. 781-782)
.,... Plasmodesmata: Continuously Changing Structures
CHAPTER THIRTY-SIX
Plasmodesmata can change in number. When dilated, they can provide a passageway for macromolecules such as RNA and proteins.
Resource Acquisition and Transport in Vascular Plants
783
....,. Electrical Signaling in the Phloem The phloem can conduct nerve-like electrical signals that propagate through the
symplast and help to integrate whole-plant function.
....,. Phloem: An Information Superhighway Phloem helps integrate whole-plant function by transporting proteins, RNAs,
and other macromolecules over long distances.
TESTING YOUR KNOWLEDGE
SELF-QUIZ
1. Which of the following does not affect self-shading?
a. leaf area index
d. stem thickness
b. phyllotaxy
e. leaf orientation
c. self-pruning
2. What would enhance water uptake by a plant cell?
a. decreased \jl of the surrounding solution
b. an increase in pressure exerted by the cell wall
c. the loss of solutes from the cell
d. an increase in \jl of the cytoplasm
e. positive pressure on the surrounding solution
3. A plant cell with a \j/s of -0.65 MPa maintains a constant
volume when bathed in a solution that has a \j/s of -0.30 MPa
and is in an open container. The cell has a
a. \j/p of +0.65 MPa.
d. \j/p of +0.30 MPa.
b. \jl of -0.65 MPa.
e. \jl of 0 MPa.
c. \jlp of +0.35 MPa.
d. photolysis, the water-splitting step of photosynthesis,
cannot occur when there is a water deficiency.
e. accumulation of C0 2 in the leaf inhibits enzymes .
8. Stomata open when guard cells
a. sense an increase in C0 2 in the air spaces of the leaf.
b. open because of a decrease in turgor pressure.
c. become more turgid because of an addition of K+,
followed by the osmotic entry of water.
d. close aquaporins, preventing uptake of water.
e. accumulate water by active transport.
9. Movement of phloem sap from a source to a sink
a. occurs through the apoplast of sieve-tube elements.
b. may translocate sugars from the breakdown of stored
starch in a root up to developing shoots.
c. depends on tension, or negative pressure potential.
d. depends on pumping water into sieve tubes at the source.
e. results mainly from diffusion.
10. Which of these is not transported via the symplast?
a. sugars
d. proteins
b. mRNA
e. viruses
c. DNA
11. i•i;f-Sitliil Trace the uptake of water and minerals from root
hairs to the vessels in a root, following a symplastic route and
an apoplastic route. Label the routes.
4. Which structure or compartment is not part of the apoplast?
a. the lumen of a xylem vessel
b. the lumen of a sieve tube
c. the cell wall of a mesophyll cell
d. an extracellular air space
e. the cell wall of a root hair
5. Which of the following is an adaptation that enhances the
uptake of water and minerals by roots?
a. mycorrhizae
b. cavitation
c. active uptake by vessels
d. rhythmic contractions by cortical cells
e. pumping through plasmodesmata
6. Which of the following is not part of the transpirationcohesion-tension mechanism for the ascent of xylem sap?
a. loss of water from the mesophyll cells, which initiates a
pull of water molecules from neighboring cells
b. transfer of transpirational pull from one water molecule to
the next, due to cohesion by hydrogen bonds
c. hydrophilic walls of tracheids and vessels that help
maintain the column of water against gravity
d. active pumping of water into the xylem of roots
e. lowering of \jl in the surface film of mesophyll cells due to
transpiration
7. Photosynthesis ceases when leaves wilt, mainly because
a. the chlorophyll of wilting leaves breaks down.
b. flaccid mesophyll cells are incapable of photosynthesis.
c. stomata close, preventing C0 2 from entering the leaf.
784
UNIT SIX
Plant Form and Function
For Self-Quiz answers, see Appendix A.
MMi•lf·M
Visit www.campbellbiology.com for a Practice Test.
EVOLUTION CONNECTION
12. Large brown algae called kelps can grow as tall as 25m. Kelps consist of a holdfast anchored to the ocean floor, blades that float at the
surface and collect light, and a long stalk connecting the blades to
the holdfast (see Figure 28.15). Specialized cells in the stalk, although
nonvascular, transport sugar. Suggest a reason why these structures
analogous to sieve-tube elements might have evolved in kelps.
SCIENTIFIC INQUIRY
13. Tomato and cotton plants wilt within a few hours of flooding
their roots. Flooding leads to low oxygen conditions, increases
in cytoplasmic calcium, and decreases in cytoplasmic pH. Suggest a hypothesis to explain how it leads to wilting.
SCIENCE, TECHNOLOGY, AND SOCIETY
14. In the arid southwestern United States, there has been growing
criticism of water use for lawns and golf courses. Should such
use be limited or even banned? Explain.